Device for determining potential future interests to be introduced into profile(s) of user(s) of communication equipment(s)

ABSTRACT

A device (D) is intended for determining potential interests of users (U 1 -U 3 ) that are clients of at least one network operator, each user being associated to a profile defining at least his interests. This device (D) comprises i) a tracking means (TM) arranged for analyzing the profile of at least one user (U 1 ) to determine new real interest(s) it contains and for storing an identifier representative of a determined new real interest of this user (U 1 ) in correspondence with a first date at which it has been considered as a new real interest into his profile, and ii) a recommendation means (RM) arranged for analyzing the first dates of a user (U 1 ) to determine a time ordered sequence of interests preceding a determined new real interest, and for comparing this determined user interest sequence to at least one other sequence RM of interests of at least one other user (U 2 ) to predict at least one potential future interest for this user (U 1 ), to be introduced into his profile.

The present invention relates to the recommendation of content items for users of communication equipments capable of being connected to at least one communication network, and more precisely to personalization of user content recommendations.

One means here by “user profile” a set of data (or metadata) describing the identity of a user, such as socio-demographic data and interests (or preferences or else habits) relative to one or more subjects (television programs, radio programs, news, music, advertising, entertainment, items to buy or use of services, for instance). (Meta)Data describing user interests can be words or expressions or else concepts that most of the time may be found also in the descriptions that are associated to the content items.

Moreover, one means here by “user content recommendations” recommendations (or suggestions) of content items that are proposed to a user based on interests (or preferences or else habits) contained into his profile.

More, one means here by “concept” something defined by one or more words or from one or several taxonomies or ontologies, and therefore associated to a semantic content. It is usually described by a set of at least one property (i.e. a set of descriptors having a type and a value).

One major challenge in the domain of personalization of user content recommendations is to understand the interests of users as properly as possible in order to provide them with content items suited to their respective needs.

As it is known by the man skilled in the art, usual techniques for content recommendation (such as content-based filtering algorithms) do not allow introducing in the user profiles concepts that did not appear in the descriptions of content that have been consumed by the users. Indeed, when a content item is consumed by a user, metadata that describe this content item can be added (according to various heuristics) to the user profile, and then recommendations are generated on the basis of similarities between the user profile and the content metadata. So, content items for which there are no corresponding metadata in a user profile will not be recommended to the user.

These approaches tend to overspecialise the recommendations and do not enable to add enough diversity/discovery in the recommendations. More precisely, these approaches do not allow anticipating user interests: the user must have consumed something described by a concept (or equivalent) to have further recommendations related to that concept. For example, with existing systems if a user liked one book of Victor Hugo, the recommender system will tend to recommend him other books of Victor Hugo, whereas this user (but also many others) may be interested in discovering other writers, just because his (their) taste(s) evolve(s) naturally with time and also because of the influence of the items he (they) has (have) consumed, and of other interests he (they) may have had in the meantime.

Other approaches have been recently proposed to improve the user content recommendations.

A first approach concerns the so-called “collaborative recommenders”. Typical collaborative recommenders comprise a core mechanism consisting in finding hidden links between users based on the similarity of their preferences or historic behaviour. Items are recommended to a certain user with respect to the interests he shares with other users or according to opinions, comparatives, and ratings of items given by other users having similar profiles.

So, in this first approach, the comparison between users and items is done globally, without taking into account the temporal dimension, and therefore this approach may be not very relevant when there is a strong dependency between two items. Moreover, even if collaborative recommenders allow to bring some diversity in the recommendations, they are not able to address directly the problem of anticipating the next (or future) user interests. More, collaborative recommenders require a significant number of user ratings in order to be effective (this is the so called “cold-start problem”).

A second approach concerns the so-called “frequent pattern mining algorithms”. These algorithms enable finding dependencies between the appearance of items in a set of transactions, as described notably in the article of Goethals, B., “Survey on frequent pattern mining”, Technical report, Helsinki Institute for Information Technology, 2003. The goal of a frequent pattern mining algorithm is to find a set of frequent and confident association rules of the form “X

Y”, which means: “if the set of items X appears in a transaction, then another set of items Y also appears in that transaction”. An association rule is considered as frequent if the ratio between the number of transactions in which X and Y appear together and the total number of transactions satisfies a frequency threshold. Similarly, an association rule is confident if the percentage of transactions where X and Y appear together among all transactions containing X is greater than a confidence threshold.

Even if frequent pattern mining algorithms enable finding relationship between items, they are only concerned with the presence of items in transactions, but they do not consider the moment of appearance of preferences (or items). There exist approaches for frequent temporal pattern mining (for example the one described in the article of Sivaselvan, B. et al, “An efficient frequent temporal pattern mining algorithm,” Information Technology Journal, vol. 5, pp. 1043-1047, 2006) which takes into account the order of appearance of items in transactions. However, the temporality is considered in terms of the number of items separating the two frequent sets of items and not in terms of the time elapsed between them.

A third approach concerns the so-called “temporal probabilistic models”. Some probabilistic models have been proposed for user interest and interest transition capturing and predicting. They have been notably described in the article of Suzuki, T. et al., “Learning to estimate user interest utilizing the Variational Bayes' estimator”, Proceedings of 5th International Conference on Intelligent Systems Design and Applications, Wroclaw, Poland, 94-99, 2005, and in the article of Wang, S. et al, “Mining Interest Navigation Patterns with Hidden Markov Model”, Lecture Notes in Computer Science Volume 4027/2006, pp. 470-478, Springer, 2000.

These last models have been conceived for single user interest transition capturing, but not for applying captured interest transition patterns of one user to similar users.

So the object of this invention is to anticipate future users' interests, in order to improve users' acceptance and confidence in recommender systems, and alleviate drawbacks of content-based recommender systems which require prior observations prior to updating user interests.

For this purpose, the invention provides a device, intended for determining potential interest(s) of user(s) that is/are client(s) of at least one network operator, each user being associated to a profile defining at least his interests, and comprising:

-   -   a tracking means arranged for analyzing the profile of at least         one user to determine new real interest(s) it contains and for         storing an identifier representative of a determined new real         interest of this user in correspondence with a first date at         which it has been considered as a new real interest into his         profile, and     -   a recommendation means arranged for analyzing the first dates of         a user to determine a time ordered sequence of interests         preceding a determined new real interest and for comparing this         determined user interest sequence to at least one other sequence         of interests of at least one other user to predict at least one         potential future interest for said user, to be introduced into         his profile.

The device according to the invention may include additional characteristics considered separately or combined, and notably:

-   -   its recommendation means may be arranged for comparing the         determined user interest sequence to at least one other sequence         of interests, determined into a graph of interests built from         the interests of other users, to predict at least one potential         future interest of this user;         -   its recommendation means may be arranged for building and             updating the interest graph from the stored real interests             of the users;     -   Its recommendation means may be arranged for building and         updating an interest graph which models the evolution of         interests over time for a plurality of users;     -   in a variant, its recommendation means may be arranged for         building and updating an auxiliary interest graph which models         the evolution of interests over time for one user then for         aggregating this auxiliary interest graph with auxiliary         interest graphs built for other users to produce an interest         graph;     -   its recommendation means may be arranged for building and         updating a directed and weighted interest graph G(V, W), where V         is a set of nodes representing respectively the user interests,         and W is a set of directed edges representing a transition from         a user interest to another user interest;         -   its recommendation means may be arranged for assigning a             weight to each of the directed edges, each weight being             defined by a table establishing a correspondence between             each user and an elapsed time between the appearances of             first an second consecutive real interests;     -   its recommendation means may be arranged for updating the         interest graph each time it is informed by the tracking means         that it has determined a new real interest of a user;     -   its recommendation means may be arranged for determining at         least one statistical metric from the weights assigned to the         directed edges and for using each determined statistical metric         with heuristics to suggest interests adapted to a chosen         applicative context and then to predict at least one potential         future interest for the user from these suggested interests:         -   at least one statistical metric may be representative of the             relevance between two interests;         -   at least one statistical metric may be representative of the             frequency of a transition between two interests;     -   its tracking means may be arranged for determining the         consumption of content items of the user that are related to an         interest contained into his profile and for considering that         this interest is a new real interest when this determined         consumption of the related content items is greater than a         chosen threshold;         -   its tracking means may be arranged for considering that the             first date of an interest is the date at which it detects             that a content item consumption related to this interest is             greater than the chosen threshold;     -   its recommendation means may be arranged for determining a         favourable date for introducing the potential future interest         into the profile of the user.

The invention also provides a network equipment, for at least one communication network, and comprising a device such as the one above introduced, intended for working in a centralized manner to predict potential future interests for a plurality of users.

The invention also provides a user communication equipment intended for being connected to at least one communication network, and comprising a device such as the one above introduced, intended for predicting potential future interests for its user.

Other features and advantages of the invention will become apparent on examining the detailed specifications hereafter and the appended drawings, wherein:

FIG. 1 schematically illustrates a communication network to which are coupled three communication equipments of users and a network equipment comprising an example of embodiment of a device according to the invention,

FIG. 2 is a diagram illustrating an example of evolution of an interest strength (IS) of a user over time (t),

FIG. 3 schematically illustrates an example of interest graph concerning n users, and

FIG. 4 schematically illustrates an example of algorithm intended for building and updating an interest graph iteratively.

The appended drawings may serve not only to complete the invention, but also to contribute to its definition, if need be.

The invention aims at offering a device (D) intended for providing potential interest(s) to at least one user (Uj) i) that is client of a network operator, ii) which is equipped with a communication equipment (CE) capable of being connected to a communication network (CN) of this network operator, and iii) which is associated to a profile defining at least his interests.

As mentioned in the introductory part, one means here by “user profile” a set of data (or metadata) describing the identity of a user, such as socio-demographic data and interests (or preferences or else habits) relative to one or more subjects (television programs, radio programs, news, music, advertising, entertainment, items to buy or use of services, for instance). (Meta)Data describing user interests can be words or expressions or else concepts that most of the time may be found also in the descriptions that are associated to the content items.

In the following description it will be considered as example that the communication network (CN) is a wired network, for instance of an ADSL type. But the invention is not limited to this type of communication network. Indeed, it concerns any type of communication network, and therefore as well wireless networks as wired networks.

Due to this assumption, it will be considered in the following description that the user communication equipments (CE) are fixed or portable computers. But the invention is not limited to this type of communication equipment. Indeed, it concerns any type of communication equipment capable of being connected to a wireless network and/or a wired network. So, a communication equipment could be also a fixed or mobile phone, a personal digital assistant (or PDA), or a set-top box (STB), for instance.

As illustrated in the non limiting example of FIG. 1, a device D, according to the invention, may be localized into a network equipment SS connected to a communication network CN of a network operator. This network equipment SS may be, for instance, a server SS which is dedicated to the access to information relative to users Uj that are clients of the network operator. This server SS may be a recommender system, for instance. So, in this example the device D works in a centralized manner for a plurality of users Uj (here j=1 to 3). But this device D could be also coupled to a network equipment (also for working in a centralized manner), or located into, or coupled to, a user communication equipment CE for working in a distributed manner for a single user Uj.

This device D can be made of a combination of electronic circuit(s) (or hardware modules) and software modules. In this case it further comprises a software interface allowing interworking between the hardware and software modules. But it could be also made of electronic circuit(s) or of software modules (in this last case it can be stored in a memory or in any computer software product, such as a CD-ROM, for instance).

A device D according to the invention comprises a tracking module TM and a recommender module RM.

This tracking module TM is intended for analyzing the profile of at least one user Uj. It is important to note that in the described example the device D works in a centralized manner for a plurality of users Uj (here j=1 to 3). So it is arranged for analyzing the profiles of all the users Uj of this plurality, which are stored into a first storage means SM1 which belongs to the network operator, for instance, and which are connected to (as illustrated) or comprise into the communication network CN. But in a variant in which the device D is associated to a single user communication equipment CE, the tracking module TM is arranged for analyzing the only profile of this user Uj, which can be stored into a storage means of the user communication equipment CE.

Every analysis is carried out by a sub module TSM of the tracking module TM and aims at determining each new real interest contained into the analyzed user profile. A “new real interest” is either an interest which was already contained into a user profile during a preceding analysis but which was not yet considered as really important for this user, or an interest which was not contained into a user profile during the last analysis and which is immediately considered as really important for this user. So, it is not mandatory that a new real interest be a very new (or recent) interest.

To decide whether an interest (contained into a user profile) is really important for this user Uj, the tracking module TM (and more precisely its sub module TSM) may be arranged for determining the consumption of content items of this user Uj that are related to this interest, and for considering that this interest is a (new) real interest when this determined consumption of the related content items is greater than a chosen threshold T_(IS). This determination of content item consumption can be carried out by the tracking module TM (via the server SS) into the communication network CN (for instance into the server(s) delivering the content items) or into the concerned user communication equipment CE.

An example of evolution over time t of an interest strength IS, representative of the consumption by a user Uj of content items relating to an interest contained into his profile, is illustrated in the diagram of FIG. 2. Generally speaking the interest strength IS is a function of the content consumption. In this diagram the time t is given in days (but it could be also given in months or weeks or else hours depending on the manipulated data and/or concerned application—more generally the unit (t) is chosen to be the most appropriate to describe the evolution of interest strength IS over time (t)) and the chosen threshold T_(IS) is equal to 0.72. Moreover in this example the tracking module TM considers that the interest became really important at the date t_(a) which corresponds to the time when the IS curve became greater than the threshold T_(IS), i.e. at t_(a)=6.4 days. This date t_(a) will be called a first date hereafter.

Once the tracking module TM (and more precisely its sub module TSM) has considered that an interest of a user Uj is really important, it stores an identifier representative of this interest in correspondence with an identifier of this user Uj and with the first date at which it has been considered as a new real interest into his profile. The sub module TSM may store the above mentioned data into a second storage means SM2 which may be part of the tracking module TM as illustrated. This second storage means SM2 may be of any type known from the man skilled in the art. So, it may be a database or a repository or else a memory, for instance.

Preferably, the tracking module TM also stores a second date t_(d) into the second storage means SM2, in correspondence with an interest identifier, an user identifier and a first date t_(a), when it considers that this user interest is no more a real interest for this user (i.e. when the interest strength IS of this user interest became smaller than the chosen threshold T_(IS)). In the diagram of FIG. 2, the second date t_(d) which corresponds to the time when the IS curve became smaller than the threshold T_(IS), is equal to 20.6 days.

The recommendation module RM (of the device D) is arranged for analyzing the first dates t_(a) of a user Uj that are stored into the second storing means SM2. This analysis is carried out by a sub module RSM of the recommendation module RM and is intended for determining a time ordered sequence of interests which precede an interest that has just been considered by the tracking module TM as a new real interest for a user Uj.

The recommendation module RM may be informed of the appearance of a new real interest of a user Uj by the tracking module TM or by analyzing the content of the second storage means SM2 on request or automatically (for instance periodically).

A time ordered sequence of interests of a user Uj is a sequence which comprises a list of interests of this user Uj which are ordered according to the first date t_(a) that are stored into the second storage means SM2 in correspondence of their respective interest identifiers and user identifiers.

Once the sub module RSM has determined a time ordered sequence of interests for a user Uj, it compares this determined user interest sequence to at least one other sequence of interests of at least one other user Uj′ (j′ ≠j) to predict at least one potential future interest for this user Uj, in order this potential future interest could be introduced into the profile of this user Uj or at least proposed to this user Uj.

So, contrary to known methods, the invention does not recommend items, but it recommends future (or potential) interests for a user Uj, based on sequence(s) of past interests of this user Uj, and on sequences of other interests of other user(s).

The invention exploits temporal dependencies between user interests, which are currently ignored in existing approaches of recommender systems, and which may be deduced from the sequence of interests of other users Uj′ if one assumes that some users have similar evolution of their tastes and interests over time. For instance, a user Uj, that starts to be interested in jazz music, may be rapidly interested in a music genre related to jazz music, and/or on specific artist(s) playing notably jazz music, and/or on a sub-genre of jazz music, such as jazz manouche, and/or in concerts related to that emerging interest. In an other example, an interest of a user Uj for a particular natural disaster may trigger interests in social aspects and/or economy. In still an other example, an interest of a user Uj for fashion may trigger a more general interest for online shopping.

The recommendation module RM (and more precisely its sub module RSM) may be arranged for comparing a user interest sequence, that it has just determined into the data relating to this user Uj and stored into the second storage means SM2, to at least one other sequence of interests (preferably the longest one), which can be determined into a graph of interests that has been built from the interests of other users Uj′, in order to predict at least one potential future interest of this user Uj.

Such a graph of interests can be built and updated by the recommendation module RM (and more precisely by its sub module RSM) from the data which define the real interests of the users Uj and which are stored into the second storage means SM2.

The sub module RSM may store the interest graph into a third storage means SM3, which may be part of the recommendation module RM as illustrated. This third storage means SM3 may be of any type known from the man skilled in the art. So, it may be a repository or else a memory, for instance.

For instance, the graph of interests may model the evolution of interests over time for a plurality of users Uj. It can be built and updated either directly from the stored data or by means of an aggregation of interest graphs. The last case is more particularly adapted to a situation in which devices D are distributed in the user communication equipments CE. In this case the recommendation module RM (and more precisely its sub module RSM), which belongs to the device D associated to a user Uj, may be arranged for building and updating an auxiliary interest graph, which models the evolution of interests over time for this user Uj, and then for aggregating this auxiliary interest graph with auxiliary interest graphs, built for other users Uj′ (by their respective associated devices D), in order to produce an interest graph.

The interest graph may be a directed and weighted graph G(V, W), where V is a set of nodes which represent respectively the user interests, and W is a set of directed edges, which each represent a transition from a user interest i_(n−1) to another user interest i_(n).

A non limiting example of such a directed and weighted interest graph G(V, W) is illustrated in FIG. 3. Six nodes A, B, C, D, E and F, corresponding respectively to six user interests, constitute this graph G(V, W) with a set of eight directed edges W in this example. More precisely there is a directed edge W_(AB) between nodes A and B, a directed edge W_(BC) between nodes B and C, a directed edge W_(BD) between nodes B and D, a directed edge W_(CF) between nodes C and F, a directed edge W_(DE) between nodes D and E, a directed edge W_(DF) between nodes D and F, and a directed edge W_(EF) between nodes E and F.

A weight is assigned to each directed edge W, for instance by the recommendation module RM (and more precisely by its sub module RSM). As illustrated in the non limiting example, each weight may be defined by a table T(W_(AB)) (or T(W_(BC)) or . . . or else T(W_(EF))). For instance the illustrated table T(W_(AB)), which is associated to the directed edge W_(AB), establishes a correspondence between each user Uj (j=1 to n, for instance n=3) and an elapsed time Δt_(ABj) between the appearances of the two consecutive real interests that are associated respectively to nodes A and B.

For instance, one assumes that the last known real interests that appeared for a user Uj are those represented by nodes B, D and C in the graph of FIG. 2. Nodes B, D and C constitutes the ordered interest sequence of user Uj. In this illustrated example of graph, node C is connected to nodes B and F, and node D is connected to node B, E and F, but node D is not connected to node C. So one possible transition is from node C to node F. However, given that this transition (C-F) relies only on the last known interest of user Uj, this transition may be a bit weak and of relative low confidence, because in the graph, neither E nor D is connected to C. So, if one ignores node C and considers the previous interest of user Uj (represented by node D), one can see that node D has node B for predecessor in the graph, which represents also a predecessor of the user interest (represented by node D). Therefore one can consider the interests, which are respectively represented by nodes E and F, as potential future interests for user Uj.

If there exists several potential future interests for user Uj (as in the above example), the recommendation module RM (and more precisely its sub module RSM) may compute one or more statistical metrics from the weights of the directed edges W, and then use each determined statistical metric to choose the most appropriate potential future interest.

For instance the sub module RSM may compute a statistical metric such as the standard deviation to estimate the relevance of a transition between two nodes of a graph (and therefore the two corresponding interests). For instance, if the dispersion of values is very high, the transition may be exploitable enough.

The sub module RSM may also compute a statistical metric such as the relative number of entries in the table (or weight) of a directed edge W to estimate the frequency of a transition between two interests, which may indicate if this transition is main stream or if it is something more particular.

Based on these statistical metrics, it is possible to build heuristics that will help suggesting appropriate interests adapted to a chosen applicative context and then predicting at least one potential future interest for a user Uj from these suggested interests. For example, depending on the application context, it may be more interesting to emphasize non-main stream evolutions of user interests because it could lead to “long-tail” content.

An heuristic may consist in looking into the interest graph for the longest sequence of interests i_(k), i_(k+1), . . . , i_(n) extracted from the known sequence of interests of the considered user Uj. It is also possible to relax the search by considering incomplete sequences, especially in the case where the determined relevance metric between two possible interests is low or if the frequency of the transition between two possible interests is low, which means that this is a marginal transition. So, one can select the next node i_(n+1) in the interest graph for which the frequency of transition between i_(n) and i_(n+1) is the highest (this heuristic favors a main stream interest evolution).

The recommendation module RM (and more precisely its sub module RSM) may be also arranged for determining a favourable date for introducing a potential future interest into the profile of a user Uj. For this purpose, it may, for instance, use the weight(s) of the directed edge W between the last interest of this user Uj and the predicted one(s). For instance, it may compute the average value (average(Δt_(AB))) of the table associated to the selected directed edge W and then wait until a timer, scheduled with this average value, expires before recommending the new corresponding interest to the user Uj or before recommending this new corresponding interest in order it could be introduced into the profile of this user Uj.

To predict a future interest of a given user Uj, the recommendation module RM may implement an algorithm such as the one described hereafter with reference to FIG. 4.

This algorithm begins with a step 10 when a new real interest i_(n) has been detected for a user Uj by the tracking module TM.

Then in a step 20 one (RM) carries out a first test to determine if this new real interest i_(n) is already present as a node in the interest graph. If this is not the case, one (RM) adds a new node (representing the new real interest i_(n)) to the interest graph, in a step 30.

Then in a step 40 one (RM) creates a link (or directed edge W) between the two nodes representing interests i_(n−1) and i_(n) in the interest graph.

Then one (RM) computes a weight for the link (or directed edge W) between the two nodes representing interests i_(n−1) and i_(n) in the interest graph, in a step 60.

Now, if the first test carried out in step 20 indicates that the new real interest i_(n) is already present as a node in the interest graph, one (RM) carries out a second test in step 50 to determine if a link (or directed edge W) between the two nodes representing interests i_(n−1) and i_(n) exists in the interest graph. If this is not the case, one (RM) carries out step 40 (to create a new link) and then step 60 (to compute a weight for this new link).

If the second test indicates that the link (or directed edge W) between the two nodes representing interests i_(n−1) and i_(n) exists already in the interest graph, one (RM) carries out step 60 to update the weight of this link. This would enable to recommend to the user Uj a content in relationship to that interest, without waiting for a long time until this user Uj would have consumed enough content related to that interest. So, thanks to the invention, the user may have access faster to content he may be interested in, even before he has demonstrated a proven interest for this type of content.

The invention can provide significant advantages to content-based filtering algorithms (because it avoids over specialisation) without having the same issue(s) as the one(s) presented by collaborative filtering methods (such as cold-start). Moreover the invention does not need user ratings.

The invention is not limited to the embodiments of device, network equipment and communication equipment described above, only as examples, but it encompasses all alternative embodiments which may be s considered by one skilled in the art within the scope of the claims hereafter. 

1. Device (D) for determining potential interest(s) of user(s) (Uj) that is/are client(s) of at least one network operator, each user (Uj) being associated to a profile defining at least his interests, wherein it comprises i) a tracking means (TM) arranged for analyzing the profile of at least one user (Uj) to determine new real interest(s) it contains and for storing an identifier representative of a determined new real interest of said user (Uj) in correspondence with a first date at which it has been considered as a new real interest into his profile, and ii) a recommendation means (RM) arranged for analyzing the first dates of a user (Uj) to determine a time ordered sequence of interests preceding a determined new real interest and for comparing this determined user interest sequence to at least one other sequence of interests of at least one other user (Uj′) to predict at least one potential future interest for said user (Uj), to be introduced into his profile.
 2. Device according to claim 1, wherein said recommendation means (RM) is arranged for comparing said determined user interest sequence to at least one other sequence of interests, determined into a graph of interests built from the interests of other users (Uj′), to predict at least one potential future interest of said user (Uj).
 3. Device according to claim 2, wherein said recommendation means (RM) is arranged for building and updating said interest graph from the stored real interests of said users (Uj).
 4. Device according to claim 1, wherein said recommendation means (RM) is arranged for building and updating an interest graph which models the evolution of interests over time for a plurality of users (Uj).
 5. Device according to claim 1, wherein said recommendation means (RM) is arranged for building and updating an auxiliary interest graph, which models the evolution of interests over time for one user (Uj), then for aggregating said auxiliary interest graph with auxiliary interest graphs, built for other users (Uj′), to produce an interest graph.
 6. Device according to claim 4, wherein said recommendation means (RM) is arranged for building and updating a directed and weighted interest graph G(V, W), where V is a set of nodes representing respectively said user interests, and W is a set of directed edges representing a transition from a user interest to another user interest.
 7. Device according to claim 6, wherein said recommendation means (RM) is arranged for assigning a weight to each of said directed edges, each weight being defined by a table establishing a correspondence between each user and an elapsed time between the appearances of first an second consecutive real interests.
 8. Device according to claim 4, wherein said recommendation means (RM) is arranged for updating said interest graph each time said tracking means (TM) informs it that it has determined a new real interest of a user (Uj).
 9. Device according to claim 6, wherein said recommendation means (RM) is arranged for determining at least one statistical metric from said weights assigned to said directed edges and for using each determined statistical metric with heuristics to suggest interests adapted to a chosen applicative context and then to predict at least one potential future interest for said user (Uj) from said suggested interests.
 10. Device according to claim 9, wherein at least one statistical metric is representative of the relevance between two interests.
 11. Device according to claim 9, wherein at least one statistical metric is representative of the frequency of a transition between two interests.
 12. Device according to claim 1, wherein said tracking means (TM) is arranged for determining the consumption of content items of said user (Uj) that are related to an interest contained into his profile and for considering that this interest is a new real interest when said determined consumption of the related content items is greater than a chosen threshold.
 13. Device according to claim 12, wherein said tracking means (TM) is arranged for considering that the first date of an interest is the date at which it detects that a content item consumption related to said interest is greater than said chosen threshold.
 14. Device according to claim 1, wherein said recommendation means (RM) is arranged for determining a favourable date for introducing said potential future interest into the profile of said user (Uj).
 15. Network equipment (SS) for at least one communication network (CN), wherein it comprises a device (D) according to claim 1, intended for working in a centralized manner to predict potential future interests for a plurality of users.
 16. Communication equipment (CE) for a user (Uj), intended for being connected to at least one communication network (CN), wherein it comprises a device (D) according to claim 1, intended for predicting potential future interests for said user (Uj). 